磁质谱法测定高丰度稳定同位素样品中氙锗硼硅丰度

doi:10.13228/j.boyuan.issn1000-7571.012391

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摘要高丰度气体同位素中丰度测定是离心法生产稳定同位素产品的重要环节。本研究采用改造的磁质谱仪,根据高丰度同位素样品氙气、四氟化锗、四氟化硅和三氟化硼电离后的谱图分析确定了各气体同位素丰度表征离子,并根据离子在磁场中的运动特征确定了法拉第杯及磁场位置,建立了一种高丰度气体稳定同位素样品(丰度大于99%)氙气、四氟化锗、四氟化硅和三氟化硼中氙、锗、硅和硼同位素丰度的质谱分析方法。测量结果表明,丰度最高的同位素为¹²⁴Xe(99.955 4%),其相对标准偏差(RSD)为0.002%;四氟化锗中的⁷⁶Ge由天然丰度7.8％浓缩到了99.071％,各同位素测量结果的相对标准偏差均不大于1.6%,其中高丰度⁷⁶Ge为0.01%;四氟化硅中²⁸Si的丰度达到了99.989 5%,各同位素丰度测量结果相对标准偏差均不大于1.4%;三氟化硼中¹¹B丰度达到99.975 7%,¹⁰B和¹¹B同位素丰度测量结果相对标准偏差最大为0.17%。在气体稳定同位素丰度检测过程中,增加反复抽空并测量的环境钝化步骤会有效降低记忆效应,尤其在高丰度稳定同位素检测过程中效果尤为明显。

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	曹金浩
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关键词 ：高丰度, 气体稳定同位素, 质谱分析, 氙, 锗, 硼, 硅

Abstract：The determination of abundance in high abundance gas isotopes is an important step in the production of stable isotope products by centrifugation. In this study, a modified magnetic mass spectrometer was used to analyze the isotopic abundance characterization ions of each gas based on the spectra of xenon gas, germanium tetrafluoride, silicon tetrafluoride, and boron trifluoride after ionization in high abundance isotope samples. The Faraday cup and magnetic field positions were determined based on the motion characteristics of ions in the magnetic field. A mass spectrometry analysis method of isotopic abundance of xenon, germanium, silicon, and boron in high abundance gas stable isotope samples (abundance greater than 99%) xenon,of germanium tetrafluoride, silicon tetrafluoride, and boron trifluoride was established. The measurement results indicated that the isotope with the highest abundance was ¹²⁴Xe (99.955 4%), with a relative standard deviation (RSD) of 0.002%. The natural abundance of ⁷⁶Ge in germanium tetrafluoride was concentrated from 7.8% to 99.071%, and the RSD of measurement result of each isotope was not greater than 1.6% (among them, the RSD of high abundance ⁷⁶Ge was 0.01%). The abundance of ²⁸Si in silicon tetrafluoride reached 99.989 5%, and the RSD of measurement result of each isotope abundance was not greater than 1.4%. The abundance of ¹¹B in boron trifluoride reached 99.975 7%, and the maximum RSD of ¹⁰B and ¹¹B isotope abundance measurements was 0.17%. During the detection of abundance of gas stable isotopes, the increase of environment passivation process could effectively reduce the memory effect, especially in the determination of high abundance stable isotopes.

Key words： high abundance gas stable isotope mass spectrometry analysis xenon germanium boron silicon

收稿日期: 2023-12-04

ZTFLH:

O657.63

作者简介: 曹金浩(1991—),男,工程师,硕士,研究方向为同位素质谱分析;E-mail:caojinhaolau@163.com

引用本文:

曹金浩, 杨凤诚, 侯超, 刘佳龙. 磁质谱法测定高丰度稳定同位素样品中氙锗硼硅丰度[J]. 冶金分析, 2024, 44(5): 47-53. CAO Jinhao, YANG Fengcheng, HOU Chao, LIU Jialong. Determination of abundance of xenon,germanium,boron and silicon in high abundance stable isotope samples by magnetic mass spectrometry. , 2024, 44(5): 47-53.

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